Thickness measuring apparatus for sheet material



April 27, 1954 R. GRIFFIN 2,676,412

THICKNESS MEASURING APPARATUS FOR SHEET MATERIAL Filed Dec. 5, 1950 5 Shee cs-Sheet 1 April 27, 1954 'R- L. GRIFFIN 2,676,412

THICKNESS MEASURING APPARATUS FOR SHEET MATERIAL 5 Sheets-Sheet 2 Filed Dec. 5, 1950 17312674280? Ra er. 67:? ,0'27/ April 27, 1954 R. GRIFFIN 2,676,412

THICKNESS MEASURING APPARATUS FOR SHEET MATERIAL Filed Dec. 5, 1950 5 Sheets-Sheet 3 (94% H v l April 27, 1954 R. L. GRIFFIN 2,676,412

THICKNESS MEASURING APPARATUS FOR SHEET MATERIAL Filed Dec. 5, 1950 5 Sheets-Sheet 4 6' fly T146 #0 .1 3; -i' -i i 1 J06 9 106 2 120 o fizz/ f 56 I .57 55 i FTFFHW FWI H %+Hlb'-++H4J -L M67350? 0 erjf. 6?:W0'70 R. L. GRIFFIN April 27, 1954 5 Sheets-Sheet 5 Filed Dec. 5, 1350 r M w w r a N w MN MN QM WA u N e W Q {i J i .3 Ed kw M N3 M y \W M v MW W W &2 \fi w w I j %\%m m. M. J @N 5/ a? m MW wk mw k g NW w. J wm R J E Mm mm mm Q -Hwm ,ness in a selected area,

Patented Apr. 2 7, 1954 THICKNESS MEASURING APPARATUS FOR SHEET MATERIAL Roger L. Griflin,

Marblehead, Mass.,

assignor, by

mesne assignments, to Swift & Company, Chicago, 111., a corporation of Illinois Application December 5, 1950, Serial No. 199,256

10 Claims.

This invention relates to measuring apparatus and more particularly to apparatus for determining the thickness of sheet material such as leather.

In the processing of leather it is necessary to measure the maximum thickness of selected portions of the skins in order to determine the setting of the shaving machine for removing excess stock. The practice has been generally to determine this thickness manually by folding the skin double and making several measurements by means of a micrometer. Although these measurements are made by a skilled operator and carefully checked, their accuracy is always subject to doubt because of the judgment requiredin selecting the points at which the measurements are made.

It is accordingly the principal object of this invention to provide apparatus for automatically and accurately determining the thickness of sheet material. Further objects are to provide thickness measuring apparatus which gives an indication of only the maximum determined thickwhich gives indications in steps preselected in units of a standard thickness gauge, which determines if the thickness is greater or lesser than preselected limits, which is rapid in operation, which can be adapted to be used in conjunction with a standard area measuring machine, which does not require a skilled operator, and which advances the art generally.

In a broad aspect the invention contemplates apparatus for determining the thickness of a sheet material comprising measuring means such as a roll pivotally surface of a material as such material moves along a path, for example, upon a conveyor or conveying means so that the angular movement of the roll about a pivot is the measure of the distance between the selected pointin the path determined, for example, by the position of one or more rolls which cooperate with the measuring roll and the outer surface of the material thereby determining its thickness. Indicating means are provided which operate in response to the amount of angular movement of the roll to indicate the distance determined by the roll and therefor the thickness of the sheet. Preferably the latter means include an electric circuit for operating a plurality of signalling devices which correspond, respectively, to successive thickness measurements and are energized in response to the amount of angular movement of the roll.

In another broad aspect the indicating means include timing means such as an electronictime mounted to contact the outer delay relay for interrupting the operation thereof after a predetermined time interval to limit the distance or lengthwise dimension of the sheet which is subject to the thickness determination. When the thickness of successive pieces of sheet material such as skins is to be determined, means such as a photoelectric cell are used to initiate the operation of the indicating means in response to the presence of askin upon the conveying means. The photoelectric cell or other determining means is positioned from the measuring roll a distance measured in the direction of movement of the conveying means equal to the preselected distance from the edge of each piece at which the thickness determination is to be started. It will be evident that the relative locations of the measuring roll and the photoelectric cell determines the position with respect to the leading edge of the skin, and that the length of the cycle of the time delay relay determines the length of the area measured. It will be evident that it is also possible tovary the position at which the measurement starts by the incorporation of an adjustable time delay relay in the output circuit of the photoelectric circuit so that the effective signal therefrom can be delayed until the skin reaches the selected position. The width of the area measured is determined by the axial length of the measuring roll.

In anotheraspect the indicating means is an electrical circuit including a plurality of switches, each of which is operated by the measuring means to energize a respective signalling device which is preferably although not necessarily a visual signal such as a'lamp which indicates the maximum distance or thickness determined by the measuring means. When the measuring means is a. pivotally mounted roll, the switches are successively operated as the distance be-' tween the path traversed by the material and the roll increases as the roll is lifted due to increased thickness of the sheet material being measured.

In a more specific a respective relay, one pair of whose contacts energizes a respective signalling device. The remaining relay contacts of each relay are interconnected withthe contacts of the other relays so that only the signalling device corresponding toa maximum thickness measure is energized. Such interconnection is preferably made by providing each relay with two normally closed contacts and two normally open contacts. The relay solenoids are energized by the operation of the correlated roll operated switches to transfer the associated-relay contacts, the energizing ciraspect each switch operatesv cult for each solenoid also including in series connection with the correlated switch, one pair of the normally closed contacts of each of the relays being energized by switches subsequently closed by the pivotal movement of the roll as the thickness of the material increases. One pair of normally open contacts of each relay closed, respectively, when the corresponding relay solenoid is energized by the correlated roll switch to complete a holding circuit paralleling the roll switch, which circuit also includes the second pair of normally closed contacts of each relay energized by subsequently closed roll switches whereby only the relay solenoid associated with the roll switch closed by the maximum angular movement of the roll during a given measurement remains energized. The second pair of normally open contacts of each relay energizes a respective signalling device so that only the device corresponding to the maximum by the measuring gives an indication.

Further objects and aspects relate to various features of construction and will be apparent from a consideration of the following description and accompanying drawings wherein:

Fig. l is a side elevation view showing the thickness measuring apparatus attached to the rear of the frame of a conventional area measuring machine;

Fig. 2 is a partial plan view of the apparatus shown in Fig. 1;

Fig. 3 is a sectional view taken on line 3--3 of Fig. 1;

Fig. 4 is a fragmentary side elevation view showing the bell crank connecting the pivotal shaft of the measuring roll with the control box;

Fig. 5 is a side elevation view of the control box with the front wall partially broken away;

Fig. 6 is a section on lines -5 of Fig. 5;

Fig. '7 is a front View with the front wall partially broken away of the indicator panel;

Fig. 8; is a wiring diagram of the electrical circuit; and

Fig. 9 is a section on line 9-43, of Fig. 5.

As is best illustrated in Fig. 1, the measuring apparatus is supported upon a frame comprising two spaced, essentially horizontal channel members ill, one end of each of which is bolted or otherwise secured to the rear portion of the legs of the frame l2 of a conventional areameasuring device M. The other end of each channel member iii is supported by means of a respective leg M which is also channel-shaped in cross-section. At an intermediate point on each of the horizontal channel members It block it which is aligned with the bearing block upon the opposite channel member so that a shaft 58 carrying a conveyor roll 26 (Figs. 2 and 3') can be journaled therein. The periphery of the conveyor roll Ed is provided with a plurality of spaced, circumferential grooves wherein are carried a plurality of conveyor Wires or belts and 24 which are arranged in alternate grooves, respectively. The bolts 22 also pass around the bed roll 28 (Fig. 2) of the measuring machine M to form conveying means for receiving the skins as they emerge from the area measuring machine which operates in a well known manner and forms no part of the present invention other than that which has been discussed heretofore so that it need not be described further.

Power for operating the conveying means is taken from the bed roll 26. To this end the shaft z-za (Fig. 1) carrying the bed roll, is provided with a, sproclaetgear 38' whose; teeth engage,- a. chain 32.x

is supported a bearing thickness determined which drives a sprocket gear 34 carried upon the end of a shaft 36 iournaled in bearing blocks 38 secured to the top of the frame members W. The shaft 38 also carries a second sprocket gear fill for a chain &2 which passes over a sprocket gear 1 on a shaft 46 which is journaled in bearing blocks 48 carried near the end of the frame members Ill. The chain 52 passes under an idler gear so and over the top of a gear 52 secured to the end of the shaft l8 which carries the conveyor roll 26.

The shaft t6 carries a conveyor roll 55 (Fig. 2) having a plurality of circumferential grooves which engage the belts 26 thereby to form a second conveying means for removing the skins from the measuring apparatus, as will be described hereinafter. From the above it will be evident that rotation of the bed roll 3% drives the shaft 36 by means of chain which shaft in turn, through the chain d2, drives the shafts l8 and 46 carrying the conveyor rolls 2% and 54, respectively. By proper selection of the number of teeth on the various sprocket gears, the peripheral speed of the rolls can be made the same so that there is substantially no slippage of the belts.

The means for measuring the thickness of sheet material carried by the belts 22 comprises a plurality of backing rollers 5% which are carried on the shaft 35 and driven thereby. Cooperating with the rollers 56 is a measuring roll 60 whose ends are respectively journaled in the ends of two arms 62 which extend from a shaft 64. The ends of the shaft 64 are iournaled, respectively in upright members 5% (Fig. 1) extending from the top of the frame members It so that the measuring roll GE: is pivotally mounted with respect to the rollers 56.

From the above it will be apparent that the rollers 56 determine a definite reference point in the path of sheet material carried by the conveyor belts .22, and that, as the measuring roll 50 rides upon the top of the material, the amount of its angular movement about the shaft 64 is a function of the thickness of the material. This angular movement is measured by successively closing control switches SEE-88 (Fig. 8) (whose unction will be described hereinafter) located in a control box l0 carried below a cross member 12 (Fig. 3) extending between the frame members It. The mechanical linkage arrangement for closing the control switches in response to the rotation of the pivotal shaft 64 comprises, as is shown in Fig. 4, two arms 1 i and it which are attached, respectively, to the shaft 5*: and a switch operating shaft '18. The ends of the arms 14' and 16 are attached by pivotal connections to the respective ends of arod 80, the arms being oriented so that, as the shaft t l rotates in a counterclockwise direction as viewed in Fig. 4 in response to an increase in thickness of material, the switch operating shaft is rotated clockwise successively to close the control switches, as will be described in detail hereinafter.

it has also been found advantageous to drive the measuring roll to. This is accomplished by attaching one end of an extension shaft 82 (Fig. 3) to the measuring roll 6d. The other end of the shaft 82, carrying a sprocket gear 84, is journaled in one of the upright members E i. The gear 8 4 is driven from a sprocket geardfi carried upon the conveyor roll shaft it by means of a chain 88. To accommodate the pivotal movement of the measuring roll 60, two flexible couplings 9B are provided in the shaft 62.

As. is shown in. Figs. 1 and 3, a light source 92 'j. photoelectric; cell. at, controlling .the con.-

tacts sp (Fig. 8) of a relay, the frame of the area measuring machine means of a bracket 96. Located veyor belts upon the cross member 12 on the frame members I is a mirror box I00 having two mirrors I02 disposed so that a beam B of light from the light source 92 travels downwardly through the conveyor belts and thence to the second mirror which directs the beam back upwardly to impinge upon the photoelectric cell 94. The interruption of the light beam B by the presence of a skin on the conveyor belts 22 starts the thickness measuring operation, as will be described in detail hereinafter. The beam arrangement shown is particularly useful when measuring material having an irregular outline, such as skins wherein a scalloped or recessed leading edge might fail to interrupt a photoelectric arrangement having only a single beam in time to start the thickness measurement at the desired position. l

The arrangement for operating the control switches SZ-S8 is shown in Figs. and 6 wherein a plurality of snap action switches of the micro switch type are mounted in a row upon the rear wall I04 of the switch box which is suspended from beneath the cross member 12, as mentioned above. The switches SZ-SB are successively cperated by the rotation of the shaft 18 by means of the lever arrangement described heretofore so that, as the measuring roll 50 moves further from the rollers 56 with increasing thickness of the sheet material being measured, the switches are successively tripped.

The means for tripping each of the individual control switches ,S2S8 is comprised of a lift arm I06 and a switch contact arm I08, bothof which are carried upon the shaft .10 operatedby the push rod 80. The lift arms I06 are secured to the shaft 18 by means of pins I i0 so that they turn with the shaft. The contact arms I08yare freely rotatable upon the shaft 18 andgare biased by means of a spring II 2 so that a respective contact button I I4, carried on the end of each thereof, is brought into contact with the actuator IIIi of the correlated switch. The tension in the spring H2 is regulated by means of a respective adjusting screw- I I3 which is threaded through the rear wall I04 of the control box 10 to secure one end of the spring. The other end of each spring-i I2 is connected with the one end of a. pin I which extends transversely through thecorrelated contact arm I08. The other end of each pin I20, which extends through to the opposite side of the correlated arm I08, is rectangular in shape and has a threaded aperture therein-for receiving an adjustment screw I22 which engages a contact button I24 in the end of the associated lift arm Ill-6. The lift arms I06 are displaced angularly about the shaft 78 (Fig. 9) so that, as the shaft '18 is rotated in a clockwise direction (as viewed in Fig. 4) as the measuring roll 50 is raised, the contact buttons I24 of the lift arms I06 successively contact the ends of the respective adjustment screws I22 of contact arms-J08; therebysuccessively rotating the contact arms against the forces exerted by the springs -.I'i2. The screws I22 are adjusted so that the contacts of the switches S2S8 are successively closed by the release of their actuators H6 at intervals equivalent toa series of preselected thickness steps as measured by the movement of the measuning roll 60. Thus in Fig. 9 switch S2 has already closed, arm I60 of switch S3 has contacted the adjustment screw on arm I00 preparatory are suspended from M by 22 to contact the first mirror below the conand diagram. However, it

S3 upon further increase of I06 of succeeding to closing switch thickness, and the arms switches are spaced farther and farther from their adjusting screws so as to close the switches successively in response to continued increase in thickness. When the apparatus is used to determine the thickness of skins, it is preferable that it be calibrated to duplicate the results obtained. When a micrometer is used to measure the thickness of a skin folded double, the units of measurement are 64ths of an inch or ounces. Graded in this manner the skins are classified in eight steps as under 7 ounces, 7-8 ounces, 8-9 ounces, 9-11 ounces, 11-13 ounces, 13-15 ounces, 15-18 ounces, and "18 ounces up. As the skin is not doubled when upon the conveyor belts 22, the corresponding screw I22 is adjusted so that the contacts of the switch S2 are closed when the roll is raised 3 /2 sixty-fourths ofan inch, i. e., the equivalent of ,64 of an inch (or '7 ounces) if the skin were measured folded double. Adjustment is made so that the contacts of switches S3 through S8 close at increasing increments corresponding to the above classification.

The measurements as determined by the closing of the control switches S2 through S8 are transmitted by means of an electrical circuit, described in detail below, to the signalling devices such as the electrical lamps VI through V8 which are mounted on an indicator panel i30 (Fig. '7) behind windows I32 bearing appropriate indicia to indicate the measurement in ounces. The indicator panel I30 is preferably mounted, as is shown in Fig. 3, on the cross-head of the area measuring machine M immediately below its indicator G so that both the area and thickness of the skin can be readily determined.

The operation of the above-mentioned electrical circuit can best be understood with reference to the wiring diagram shown in Fig. 8. In this diagram three relays, which would analogously be designated L4, L5 and L6, have been omitted by providing a break in the diagram between relays L3 and L1 to simplify both the description will be apparent from the following description that any number of relays and lamps, giving any desired number of measuring steps, can be used, each relay being connected to the adjacent relays in the same manner in which relay L! is indicated to be connected to relay L3. 0

As a skin is fed between the measuring roll 60 and the rollers 56 by the belts 22, and thence proceeds to the point where as it intercepts one or the other of the light beam B portions controlling the photoelectric cell, as described heretofore, the conventional relay, associated with the contacts sp, is energized from power source terminals or and c to close the contacts. The closing of the contacts sp completes a circuit including the terminal a, the conductor cI, the normallyclosed contacts 382 of the relay L8, the conductor 02, the normally closed contacts s12 of the relay L1, and in a similar manner the conductors c3 and c4 and normally closed contacts of the remaining relays and the solenoid of the relay Li to the grounded power source terminal 0. If the thickness of the skin passing through the measuring roll 60 does not raise the roll sufliciently to close the contacts of any of the control switches S2 through 88, by the end of the timing period of the time delay relay, which is adjusted to permit a selected travel of the skin along the conveyor when the contacts st transfer, a circuit is completed including the terminal a, the photoelectric relay:

a'sregaie contacts $17, the time delay relay contacts st, a conductor c5, a conductor oil; the normally open contactsSHi of the relay Li which remains energized through the circuit described above, a sighall-ing device such as the lamp Vi to the grounded'tcrminal c thereby to illuminate the lamp l. The? lamp Vi remains illuminated for the time interval required for the skin to pass along the conveyor belts E3. to a point where it no longer interrupts the light beam B, thereby allowing the contacts of the photoelectric relay st to open. As mentioned above, the glass in front of the lampVl' bears a suitablelegend to indicate that the skin isbeneath the lower preset limit of thickness.

If the thickness of the skin is suchv that only the switch: S2 is closed by the movement of the roll 69, the solenoid or" the relay L2 is energized by a circuit including the terminal a, the photoelectric contacts sp, the time delay relay contacts st, conductors cl and 08-, the normally closed contacts siiiof the relay L 5, the conductor" 09, the normally closed contacts sli of the relay L7, the conductor clli, the normally closed contacts sill oithe'relay L3, the norm-ally closed contacts sl-il of a relayLl-ll, the contacts or the control switch S2 and the solenoid oi the relay L2 tothe terminal 0. The energizing or" the sclenoid' of the'relay'LE transfers its contacts so that a holding circuit is completed through the normally open relay contacts 5'23 so that the solenoid remains energized if the switch S2 isopened by the subsequent lowering of the roll. This holding circuit for the relay L2 comprises the conductor at, the normally closed contacts $32, the conductor 02, the normally closed contacts 512, the conductor 03, the normally closed contacts 832, the conductor 04, and the normally open relay contacts $231 When the. time delay relay con--- tacts st transfer at the end. of the-timing period, the lamp V2, behind the window marked 2-3, is illuminated by a circuit including theterminal a, the photoelectric relay contacts sp, the time delay contacts st, the conductors c5 and oil, the

normally open contacts $24 of the energized relay, L2, and the lamp V2 to the. terminal c. It will be noted that only the lamp V2 is illuminated, the circuit to lamp Vi being interrupted by theopening of the contacts Sid of the relay Li when this relay is deenergized by the opening of the contacts s2! as the relay L2 is energized, as described heretofore.

It the skin is of sufficient thickness to close the: contacts of the switch s3.,,thessolenoid of the by a circuit including the" relay L3 is energized. terminal a, the photoelectric cell relay contacts sp; the time delay relay contactsst, the conductorsi c1. and 03, the contacts sdi, the conductor 09', the contacts s'l l, the contacts ill, the switch 23-. of the relay; Llfl, and the solenoid of therelay L3. to the terminal 0. It will be; noted that the energization of the relay L3v opens $311 so that no circuit is completed through the switch S2 to energize the relayL2. The opening of the contacts 832 also precludes the energization of the relay L2 through its holding circuit. After the transfer of the time delay relay contacts st, the lamp V3 is illuminated by means of a circuit analogous to that described in detail heretofore in connection with the lamp V2;

The remaining control switches S! and S8 (and those not shown) are energized in a similar manner. The normally closed contacts of the relay Llllare provided in the circuits of the-control switches S2 through St to-prevent'i'eedbacks the contacts through sneak. circuits if several of. the: control switches should be closed simultaneously due to thicker sheet material in the area which is not selected for measuring. By energizing the solenoid oi the relay Lit upon the transferring of the time delay relay contacts st, the circuits to the control switches are opened during the portion or the measuring cycle when the lamps: V are illuminated. A test lamp" Ltl is provided which is energized through a switch sh when the time delay relay contacts st are in their normal position. The circuit for this lamp Lt is interrupted by thetransfer oi. the time delay relay contacts st, thereby providing a check upon the position of the skin as the relay contacts transfer.

It should he understood that the present disclosure is for the purpose of illustration only and that this invention includes all modifications and equivalents: which fall within the scope of the appendedclaims.

I claim:

1. Apparatus for determining the thickness of sheet material comprising a' conveyor for moving the outstretched material along a substantially horizontal path, a, roll pivotally mounted to contact the upper surface of the material as the material is moved along the path by the con.- veyor so that the angular movement of the roll about the pivot is a measure of the thickness of the material, and circuit means having? an indicator operated in response to the angular movement. of the roll to indicate the thickness determined by said roll, said circuit means including a detector for energizing saidv circuit means in response tothepresence of. the sheet material at a predetermined position inisai'd path and a timer whose timing. period is initiated by said detector for. interrupting the circuit means at the end of the timing period to limit the distance along which the thickness determination takes place.

2. Apparatus according to claim I wherein the timer is connected to energize said indicator at the end of its timing period.

3. Apparatus for determining the thickness of sheet material comprisinga plurality of wires arranged as spaced loops corresponding portions of which lie in a substantially horizontal plane, driving means for conjointly moving said wires to form a conveyor for moving the outstretched material along a substantially horizontal path, a roll pivotally mounted to contact the upper surface of the material as the material is moved along the-path by the conveyor so that the angular movement of the roll about the pivot is a measure of the thickness of the material, and circuit means having an indicator operated in re-- sponse to the angular movement of the roll to indicate the thickness determined by said roll, said circuit means including a detector for energizing said circuit means in response to the'presonce-of the sheet material at a predetermined position in said path and a timer whose timing period is initiated by said detector for interrupting the circuit means at the end of the timing period to limit the distance along which the thickness determination takes place.

l. Apparatus for determining the thickness of sheet material comprising a plurality of wires arranged as spaced loops corresponding portions of which lie in a substantially horizontal plane. driving means for coniointly moving said wires to form conveying means for moving the outstretched material along a substantially horizontal path, a plurality of backing rollers mounted below the horizontal plane of wires in spaced relationship so that the respective wires are interposed between adjacent rollers, a measuring roll pivotally mounted to contact the upper surface of the material opposite the backing rollers as the material is moved along the path by the conveyor so that the angular movement of the roll about the pivot is a measure of the thickness of the material, and circuit means having an indicator operated in response to the angular movement: of the roll to indicate the thickness determined by said roll, said circuit means including a detector for energizing said circuit means in response to the presence of the sheet material at a predetermined position in said path and a timer whose timing period is initiated by said detector for interrupting the circuit means at the end of the timing period to limit the distance along which the thickness determination takes place.

5. Apparatus according to claim 4 wherein the driving means for the conveying means conjointly operates the rollers and roll so that the peripheral speed thereof is the same as the linear speed of the wires.

6. Apparatus for determining the thickness of sheet material comprising conveying means for moving the material along a predetermined path, a roll pivotally mounted to contact the outer surface of the material as the material moves along the path so that angular movement of the roll about the pivot is a measure of the thickness of the material, circuit means including a plurality of switches and a plurality of signalling devices each of which is energized by the operation of a respective switch, and a mechanical linkage interconnecting said roll and said switches, said linkage including a rotatable shaft having a plurality of contact arms freely supported upon the shaft, a spring for biasing each arm to actuate a respective switch thereby to transfer its contacts, a plurality of lift arms fixed to the shaft with an angular relationship sequentially to move the respective contact arms thus successively returning the contacts of the switches to their normal positions as the shaft is rotated and a movable link for transmitting the angular movement of said roll to said shaft whereby the signalling device correlated with i the last returned switch gives an indication of the thickness determined by said roll.

7. Apparatus for determining the thickness of sheet material comprising conveying means for moving the material along a predetermined path,

a roll pivotally mounted to contact the outer surface of the material as the material moves along the path so that angular movement of the roll about the pivot is a measure of the thickness of the material, circuit means for indicating the maximum thickness measured by said roll, said circuit means including a plurality of switches, a plurality of relays each having a plurality of pairs of contacts which are transferred by the operation of a respective switch, and a plurality of signalling devices each of which is energized by one pair of contacts of a respective relay, and a mechanical linkage interconnecting said roll and said switches, said linkage including a rotatable shaft having a plurality of contact arms freely supported upon the shaft, a spring for biasing each arm to actuate a respective switch thereby to transfer its contacts, a plurality of lift arms fixed to the shaft with an angular relationship sequentially to move the respective contact arms thus successively returning the contacts of the switches to their normal positions as the shaft is rotated and a movable link for transmitting the angular movement of said roll to said shaft whereby the switches are sequentially operated in response to variations in the angular position of said roll, the remaining relay contacts being interconnected so that only the signalling device corresponding to the maximum thickness of the material is energized.

8; Apparatus for determining the thickness of selected portions of respective pieces of sheet material comprising conveying means for successively moving the pieces along a predetermined path, a roll pivotally mounted to contact the outer surface of each piece as the piece moves pastra'selected point in the path so that the angular movement of the roll about the pivot is a measure of the thickness of the piece, circuit means including a plurality of switches, a plurality of relays each of which is energized by the operation of a respective switch, each relay having a plurality of pairs of contacts which are transferred by the energization thereof and a plurality of signalling devices each of which is energized by the transfer of one pair of contacts of a respective relay, a linkage interconnecting said roll and said switches sequentially to actuate the switches in response to the angular movement of the roll due to variations in thickness, said circuit means also including a holding circuit for each relay having a pair of normally open contacts operated by such relay and a pair of normally closed contacts operated respectively by each of the relays energized by switches operated sequentially to such relay so that only the signalling device corresponding to the greatest thickness determination is energized at the completion of the thickness determination.

9. Apparatus for determining the thickness of sheet material comprising conveying means for moving the material along a predetermined path, a roll pivotally mounted to contact the outer surface of the materials as the material moves along the path so that angular movement of the roll about the pivot is a measure of the thickness of the material, and circuit means for indicating the maximum thickness measured by said roll, said circuit means including a plurality of switches successively operated by the angular movement of the roll as the distance between the path and the roll is increased, a plurality of relays each including two normally closed contacts, two normally open contacts and a solenoid energized by the operation of a correlated switch to transfer the associated contacts, an energizing circuit for each relay including in series connection the switch correlated with such relay and one pair of normally closed contacts of each of the relays energized by switches which are closed subsequent to the switch correlated with such relay, a holding circuit being completed upon the operation of any of the relays to parallel the correlated switch, said holding circuit including a pair of normally open contacts of such relay and the second pair of normally closed contacts of each of the relays energized by subsequently operated switches whereby only the relay solenoid associated with the switch transferred by the maximum angular movement of the roll remains energized, and a plurality of signalling devices each energized by the transfer of the second pair of normally open contacts of a respective relay so that only the device corresponding to the maxi- 1 l mum thickness gives an indication at the completion of the thickness determination.

10. Apparatus for determining the thickness of selected portions of respective pieces of sheet material comprising conveying means for successively moving the pieces along a predetermined path, a roll pivotally mounted to contact the outer surface of each piece as the piece moves past a selected point in the path so that the angular movement of the roll about the pivot is a measure of the thickness of the piece, and circuit means including a lurality of signalling devices for indicating in steps the maximum thickness measurered by said roll, said circuit means including photoelectric means for determining the presence of a piece upon the conveying means and there upon energizing the circuit means, said circuit means also including a plurality of switches and a plurality of relays each of which includes two normally closed contacts, two normally open contacts and a solenoid energized by the operation of a correlated switch to transfer the associated contacts, a linkage interconnecting said roll and said switches sequentially to actuate the switches in response to angular movement of the roll due to variations in thickness, an energizing circuit for each relay including in series connection with the switch correlated with such relay and one pair of normally closed contacts of .each of the relays energized by switches which are closed subsequent to the switch .correlated with such relay, a respective holding circuit being completed upon the operation of any of the relays to parallel the correlated switch, said holding circuit including a pair of normally open contacts of such relay and the second pair of normally closed contacts of each of the relays energized by subsequently operated switches whereby :only the relay solenoid associated with the switch transferred by the maximum angular movement oi the roll remains energized, the second pair of normally open contacts of each relayrbeing transferred to energize a respective signalling device so that only .the device corresponding to the maximum thickness gives an indication .at thecompletion of the thickness determination.

References Cited in the file of this patent UNITED STATES PATENTS 

